Jens Sörensen

Capillary Transit Time Heterogeneity and Flow-Metabolism Coupling after Traumatic Brain Injury

Most patients who die after traumatic brain injury (TBI) show evidence of ischemic brain damage. Nevertheless, it has proven difficult to demonstrate cerebral ischemia in TBI patients. After TBI, both global and localized changes in cerebral blood flow (CBF) are observed, depending on the extent of diffuse brain swelling and the size and location of contusions and hematoma. These changes vary considerably over time, with most TBI patients showing reduced CBF during the first 12hours after injury, then hyperperfusion, and in some patients vasospasms before CBF eventually normalizes. This apparent neurovascular uncoupling has been ascribed to mitochondrial dysfunction, hindered oxygen diffusion into tissue, or microthrombosis. Capillary compression by astrocytic endfeet swelling is observed in biopsies acquired from TBI patients. In animal models, elevated intracranial pressure compresses capillaries, causing redistribution of capillary flows into patterns argued to cause functional shunting of oxygenated blood through the capillary bed. We used a biophysical model of oxygen transport in tissue to examine how capillary flow disturbances may contribute to the profound changes in CBF after TBI. The analysis suggests that elevated capillary transit time heterogeneity can cause critical reductions in oxygen availability in the absence of ‘classic’ ischemia. We discuss diagnostic and therapeutic consequences of these predictions.

Neuromodulation in a minipig MPTP model of Parkinson disease

Large animal neuroscience enables the use of conventional clinical brain imagers and the direct use and testing of surgical procedures and equipment from the human clinic. The greater complexity of the large animal brain additionally enables a more direct translation to human brain function in health and disease. Economical, ethical, scientific and practical issues may on the other hand hamper large animal neuroscience. Large animal neuroscience should therefore either be performed in order to examine large animal species dependent problems or to complement promising small animal basic studies by constituting an intermediate research system, bridging small animal CNS research to the human CNS. We have, accordingly, during the last ten years used the Göttingen minipig to examine neuromodulatory treatment modalities such as stem cell transplantation and deep brain stimulation directed towards Parkinson disease. This has been accomplished by the development of a MPTP-based large animal model of Parkinson disease in the Göttingen minipig and the development of stereotaxic and surgical approaches needed to manipulate the Göttingen minipig CNS. The instituted changes in the CNS can be evaluated in the live animal by brain imaging (PET and MR), cystometry, gait analysis, neurological evaluation and by post mortem examination based on histology and stereological analysis.

Hypothalamic deep brain stimulation influences autonomic and limbic circuitry involved in the regulation of aggression and cardiocerebrovascular control in the Göttingen minipig.

Background: Deep brain stimulation (DBS) in the ventral tuberal hypothalamus (VTH) is currently under investigation for the treatment of severe obesity. Stimulation impact on a number of closely related hypothalamic neural systems could potentially influence normal hypothalamic function and thereby generate adverse side effects. Objective: To assess the feasibility and safety of VTH DBS in a non-primate large animal model. Methods: In the VTH of 6 Göttingen minipigs, quadropolar leads were implanted bilaterally (n = 2) or unilaterally (n = 4), using optimized MRI sequences allowing identification of major diencephalic landmarks. Heart rate, weight, behavior and nighttime locomotor activity were recorded throughout the study period. Two of the unilaterally implanted minipigs were examined with [15O]H2O positron emission tomography (PET) scans performed in DBS-off and DBS-on mode. Results: VTH DBS elicited an amplitude-dependent increase in heart rate and transient aggressive behavior. PET demonstrated that VTH DBS caused a global increase in cerebral blood flow velocities and decreased mean transit time. Conclusions: VTH DBS results in behavioral and physiological changes, which may derive from activation of closely related limbic and autonomic networks. Caution and further studies of longer length should be requested before this procedure is used more widely in humans.

Development of neuromodulation treatments in a large animal model—Do neurosurgeons dream of electric pigs?

The Göttingen minipig has been established as a translational research animal for neurological and neurosurgical disorders. This animal has a large gyrencephalic brain suited for examination at sufficient resolution with conventional clinical scanning modalities. The large brain, further, allows use of standard neurosurgical techniques and can accommodate clinical neuromodulatory devises such as deep brain stimulation (DBS) electrodes and encapsulated cell biodelivery devices making the animal ideal for basic scientific studies on neuromodulation mechanisms and preclinical tests of new neuromodulation technology for human use. The use of the Göttingen minipig is economical and does not have the concerns of the public associated with the experimental use of primates, cats, and dogs, thus providing a cost-effective research model for translation of rodent data before clinical trials are initiated.

Recurrence of chronic subdural haematomata with and without post-operative drainage

Chronic subdural haematoma is a common disease causing morbidity and mortality. Recurrence after surgical treatment is common, varying from 5% to 30% of cases. Several methods for reducing recurrence have been advocated. The aim of this study was to investigate the effect of post-operative subdural drainage. Three hundred forty-four patients were included in a retrospective study. Treatment was performed by burr hole irrigation. Groups were separated into those with post-operative drainage compared to those without. Recurrence occurred in 14% in the drained group, significantly less than 26% in the undrained group (p = 0.011). There were no differences in the complication rates. Post-operative drainage reduces recurrence of chronic subdural haematoma without increasing the complication rate. These results support those reported in several other studies. We recommend the use of post-operative subdural drainage.

Myocardial Oxygen Consumption and Efficiency in Aortic Valve Stenosis Patients With and Without Heart Failure

Background Myocardial oxygen consumption (MVO2) and its coupling to contractile work are fundamentals of cardiac function and may be involved causally in the transition from compensated left ventricular hypertrophy to failure. Nevertheless, these processes have not been studied previously in patients with aortic valve stenosis (AS). Methods and Results Participants underwent 11C‐acetate positron emission tomography, cardiovascular magnetic resonance, and echocardiography to measure MVO2 and myocardial external efficiency (MEE) defined as the ratio of left ventricular stroke work and the energy equivalent of MVO2. We studied 10 healthy controls (group A), 37 asymptomatic AS patients with left ventricular ejection fraction ≥50% (group B), 12 symptomatic AS patients with left ventricular ejection fraction ≥50% (group C), and 9 symptomatic AS patients with left ventricular ejection fraction <50% (group D). MVO2 did not differ among groups A, B, C, and D (0.105±0.02, 0.117±0.024, 0.129±0.032, and 0.104±0.026 mL/min per gram, respectively; P=0.07), whereas MEE was reduced in group D (21.0±1.6%, 22.3±3.3%, 22.1±4.2%, and 17.3±4.7%, respectively; P<0.05). Similarly, patients with global longitudinal strain greater than −12% and paradoxical low‐flow, low‐gradient AS had impaired MEE (P<0.05 versus controls). The ability to discriminate between symptomatic and asymptomatic patients was superior for global longitudinal strain compared with MVO2 and MEE (area under the curve 0.98, 0.48, and 0.61, respectively; P<0.05). Conclusions AS patients display a persistent ability to maintain normal MVO2 and MEE (ie, the ability to convert energy into stroke work); however, patients with left ventricular ejection fraction <50%; global longitudinal strain greater than −12%; or paradoxical low‐flow, low‐gradient AS demonstrate reduced MEE. These findings suggest that mitochondrial uncoupling contributes to the dismal prognosis in patients with reduced contractile function or paradoxical low‐flow, low‐gradient AS.

Brain Tissue Reaction to Deep Brain Stimulation—A Longitudinal Study of DBS in the Goettingen Minipig

The use of Deep Brain Stimulation (DBS) in treatment of various brain disorders is constantly growing; however, the number of studies of the reaction of the brain tissue toward implanted leads is still limited. Therefore, the aim of our study was to analyze the impact of DBS leads on brain tissue in a large animal model using minipigs.

Inotropic myocardial reserve deficiency is the predominant feature of exercise haemodynamics in cardiac amyloidosis

This study aimed to characterize invasive haemodynamics during exercise in subjects with cardiac amyloidosis (CA).

The Retrograde Connections and Anatomical Segregation of the Göttingen Minipig Nucleus Accumbens

Nucleus accumbens (NAcc) has been implicated in several psychiatric disorders such as treatment resistant depression (TRD), and obsessive-compulsive disorder (OCD), and has been an ongoing experimental target for deep brain stimulation (DBS) in both rats and humans. In order to translate basic scientific results from rodents to the human setting a large animal model is needed to thoroughly study the effect of such therapeutic interventions. The aim of the study was, accordingly, to describe the basic anatomy of the Göttingen minipig NAcc and its retrograde connections. Tracing was carried out by MRI-guided stereotactic unilateral fluorogold injections in the NAcc of Göttingen minipigs. After 2 weeks the brains were sectioned and subsequently stained with Nissl-, autometallographic (AMG) development of myelin, and DARPP-32 and calbindin immunohistochemistry. The minipig NAcc was divided in a central core and an outer medial, ventral and lateral shell. We confirmed the NAcc to be a large and well-segregated structure toward its medial, ventral and lateral borders. The fluorogold tracing revealed inputs to NAcc from the medial parts of the prefrontal cortex, BA 25 (subgenual cortex), insula bilaterally, amygdala, the CA1-region of hippocampus, entorhinal cortex, subiculum, paraventricular and anterior parts of thalamus, dorsomedial parts of hypothalamus, substantia nigra, ventral tegmental area (VTA), the retrorubral field and the dorsal and median raphe nuclei. In conclusion the Göttingen minipig NAcc is a large ventral striatal structure that can be divided into a core and shell with prominent afferent connections from several subrhinal and infra-/prelimbic brain areas.